Browsing by Subject "Polarity"

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    Polarity- and Intensity-Independent Modulation of Timing During Delay Eyeblink Conditioning Using Cerebellar Transcranial Direct Current Stimulation
    (SpringerLink, 2020-06) Mitroi, Jessica; Burroughs, Leah; Moussa-Tooks, Alexandra B.; Bolbecker, Amanda R.; Lundin, Nancy B.; O’Donnell, Brian F.; Hetrick, William P.; Psychiatry, School of Medicine
    Delay eyeblink conditioning (dEBC) is widely used to assess cerebellar-dependent associative motor learning, including precise timing processes. Transcranial direct current stimulation (tDCS), noninvasive brain stimulation used to indirectly excite and inhibit select brain regions, may be a promising tool for understanding how functional integrity of the cerebellum influences dEBC behavior. The aim of this study was to assess whether tDCS-induced inhibition (cathodal) and excitation (anodal) of the cerebellum differentially impact timing of dEBC. A standard 10-block dEBC paradigm was administered to 102 healthy participants. Participants were randomized to stimulation conditions in a double-blind, between-subjects sham-controlled design. Participants received 20-min active (anodal or cathodal) stimulation at 1.5 mA (n = 20 anodal, n = 22 cathodal) or 2 mA (n = 19 anodal, n = 21 cathodal) or sham stimulation (n = 20) concurrently with dEBC training. Stimulation intensity and polarity effects on percent conditioned responses (CRs) and CR peak and onset latency were examined using repeated-measures analyses of variance. Acquisition of CRs increased over time at a similar rate across sham and all active stimulation groups. CR peak and onset latencies were later, i.e., closer to air puff onset, in all active stimulation groups compared to the sham group. Thus, tDCS facilitated cerebellar-dependent timing of dEBC, irrespective of stimulation intensity and polarity. These findings highlight the feasibility of using tDCS to modify cerebellar-dependent functions and provide further support for cerebellar contributions to human eyeblink conditioning and for exploring therapeutic tDCS interventions for cerebellar dysfunction.
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    The role of ADF and cofilin in auditory sensory cell development
    (2020-12) McGrath, Jamis; Perrin, Benjamin; Cummins, Theodore; Belecky-Adams, Teri; Balakrishnan, Lata; Zhao, Bo
    Our ability to hear relies on sensory cells found in the inner ear that transduce sound into biological signals. Microvilli-like protrusions called stereocilia are bundled on the apical surfaces of these cells and allow them to respond to sound-evoked vibrations. The architecture of the stereocilia bundle is highly patterned to ensure normal hearing. Filaments of polymerized actin proteins are bundled in parallel into large cylindrical structures that define the dimensions of stereocilia. This network is then anchored to the cell by inserting into another actin-based structure called the cuticular plate, which forms a gel-like structure and facilitates the mechanical properties of the bundle. The shape of the bundle is determined through tissue-level and intrinsic polarization signaling pathways. Auditory brainstem-evoked response testing, immunofluorescence imaging, scanning electron microscopy, and biochemical labeling techniques were used to study how the ADF/cofilin family of actin filament severing and depolymerizing proteins contributes to the development of the stereocilia bundle. Loss of these proteins disrupts the normal bundle patterning process, changes the lengths and widths of stereocilia, and alters the regulation of filament ends near the ion channel at stereocilia tips that is responsible for mechanotransduction. The activity of this channel regulates ADF/cofilins and the actin at stereocilia tips. Aberrant actin growth in actin networks beneath the stereocilia bundle influences the bundle patterning process, causes dysmorphic bundles to form. This work identifies that ADF/cofilins are necessary during auditory sensory cell development to facilitate normal bundle patterning and establishes this protein family as a molecular link between mechanotransduction and stereocilia bundle maturation.